RU2632307C1 - Pneumatic hand-operated impact tool for graph works - Google Patents

Abstract

FIELD: machine engineering.

SUBSTANCE: tool has a cylindrical body with a circular partition on the inner surface of the body and through holes for air passage. The body accommodates a two-stage piston with longitudinal and radial channels dividing the body into three chambers. An anvil-tool holder with a chisel opening is fixed on one end of the cylindrical body, and on the other end a plug in the form of a cup and a handle. The handle is fixed on a connecting bushing. The handle has a union for air supply, and connected to a needle valve in the form of a conical needle with a rod and a spring and a valve body with cavity for air supply from the union. The needle valve is installed in a slot in the center of the handle. The conical needle with the rod and spring is forced into the end plug. The valve body has an annular radial groove with through hole for air supply from the union into its cavity. The connecting bushing is installed to form a gap between the connecting bushing and the cylindrical body. A gap for air passage is formed between the end plug and the handle inner surface.

EFFECT: expanded tool functionality.

7 cl, 3 dwg

Description

The invention relates to percussion devices for artistic and decorative processing of solid materials, for example metals, and can be used to apply images embedded in the surface of the processed material. Pneumatic percussion instruments are widely used in jewelry: engraving monograms, cutting for various types of stone clamps, carving on bone, wood and other works.

Known pneumatic percussion instrument for engraving company Glendo Corp (US) (patent US 5515930, publ. 05/14/1996), which contains a tip and an air pressure regulator with a foot pedal. The tip consists of a body, on one end of which there is an anvil - a tool holder, on the other - an end cap. Inside the housing there is a piston with a central rod, a head and a support in contact with the spring, which is located between the piston and the anvil. The piston oscillates due to the action of the spring and compressed air, which is supplied through the hole in the end cap of the housing. An air pressure regulator is connected to the tip, which contains a valve for regulating the air flow to the tip, a sensing element for controlling the valve, a compression spring and a foot pedal functionally connected to the compression spring to adjust the pressure of the supplied air.

The disadvantage of this device is the inconvenience of its use, which reduces the operational characteristics of the device, because there is no smooth adjustment of the idle piston tip. In this invention, it is necessary to select the force of pressing the spring pedal. With a slight pressure, the tip piston will not move and the tip will not work; when pressed firmly, the piston will move at high speed and this may affect the quality of engraving.

Also known is a pneumatic percussion instrument (US Pat. No. 6,530,435, published March 11, 2003, Applicant Lindsay Steven James), which comprises a handpiece, a foot valve for controlling the flow of air into the handpiece and a foot valve control device. The tip contains a housing with an annular protrusion inside, along which a two-stage piston oscillates, dividing the housing into three chambers. An anvil-tool holder is fixed at one end of the case, and an end cap with a handle attached to it to hold the tool during use is attached to the other. The foot valve control device allows in this invention to smoothly adjust the idle piston of the tip, which allows fine engraving.

However, the disadvantage of this device is the use of a foot pedal to control and operate the percussion instrument. When using this tool, the engraver must learn to coordinate the movement of the arm and leg, which controls the amount of air entering the tool when engraving, which complicates the job, requires a certain skill and reduces the operational characteristics of the device.

The closest in technical essence and the achieved result is a pneumatic manual percussion instrument for engraving (patent US 6691798, publ. 02.17.2004, applicant Lindsay Steven James), in which the idling is adjusted manually and the foot pedal is not used. This tool contains a cylindrical cusp with an annular jumper on the inner surface of the housing and through holes for the passage of air before and after the annular jumper. In the housing there is a two-stage piston with a longitudinal and radial channel that divides the housing into three chambers. An anvil with a hole for the cutter is located at one end of the cylindrical body. At the other end there is an end cap in the form of a glass, worn and fixed on the body with a spring in the center, which abuts against the end of the connecting sleeve, on which the handle is rigidly fixed. The connecting sleeve is mounted on a sliding fit with the ability to move along the housing along the outer surface of the plug. The movement of the sleeve is limited by the slot in the plug along which the pin moves inserted into the hole of the sleeve. A longitudinal hole is made in the connecting sleeve, into which a needle valve connected to the nozzle is inserted. The needle valve consists of a conical needle with a pusher at the end of the needle, rigidly mounted on the flange of the plug and valve body. The valve body has a channel for supplying air from the fitting. A spring is installed between the valve body and the fitting. A conical needle is installed in the channel that opens the air passage from the nozzle, which is mated to a radial annular groove in the connecting sleeve. From the annular groove, air enters the hole for the passage of air in the cylindrical body through the connecting hose.

The disadvantage of this device is the complexity of the design and manufacture, for example, the manufacture of a needle valve and a connecting sleeve having a number of slots and holes, as well as the use of connecting hoses, which reduces the reliability of the device. The tool starts to work when you press the spring located between the end cap and the handle. The force of pressing the handle will determine the force of impact of the tool during operation. This limits the operational capabilities of the tool, as requires a certain skill in using this tool.

The technical task of this invention is to expand the operational capabilities of the percussion instrument due to the fact that the proposed device starts to work when the tool cutter is pressed onto the surface of the material being processed, and the impact force will depend on the pressure force on the cutter. In addition, the tool has a simpler design, is convenient to use and can perform the functions of engraving and embossing.

The task is achieved in that the pneumatic manual percussion instrument for engraving includes a cylindrical body with an annular jumper on the inner surface of the body and through holes for air passage before and after the annular jumper, a two-stage piston with a longitudinal and radial channel is located in the body, dividing the body into three chamber, at one end of the cylindrical body an anvil-tool holder with an opening for the cutter is fixed, at the other - an end cap in the form of a glass and a handle, when the handle is mounted on a connecting sleeve mounted on a sliding fit with the ability to move up to the limiter along the outer surface of the housing, the handle has a nozzle for air supply connected to a needle valve in the form of a conical needle that blocks the air passage, with a spring and a valve body with a feed cavity air from the fitting. What is new is that the needle valve is installed in the groove in the center of the handle and the conical needle with the stem and spring abuts against the end cap inserted inside the cylindrical body. The valve body has an annular radial groove with a through hole for supplying air from the fitting to the cavity of the valve body. The connecting sleeve is installed with the formation of a gap between the connecting sleeve and the cylindrical body, also a gap is formed between the end cap and the inner surface of the handle for the passage of air. In addition, the end cap in the form of a cup has a flange at the end that rests on the end face of the cylindrical body. The gap between the end cap and the inner surface of the handle is formed by a threaded connection of the handle to the ledge formed on the surface of the connecting sleeve. The gap between the surface of the cylindrical body and the connecting sleeve is formed by a longitudinal groove on the surface of the cylindrical body. The valve body is connected to an adjusting screw mounted in the center of the handle. A second hole for the cutter is made in the anvil-tool holder, parallel to the central hole. The outer part of the anvil with holes for the cutter has a flat shape.

The invention is illustrated by drawings, where in FIG. 1 shows a general view of the tool; FIG. 2 shows a view of the tool when the piston is in its extreme position when it hits the anvil, FIG. 3 shows the anvil of the tool holder of a flat shape.

The pneumatic percussion instrument for engraving works contains (Fig. 1) a cylindrical body 1, in which an annular jumper 2 is made on the inner surface. Two through holes for air passage located before and after (above and below) the annular jumper are made in the body 1: 3 - inlet, 4 - outlet. At one end, the cylindrical body 1 has a protruding key 5 and an annular groove 6 with a sealing ring for a snug fit of the anvil-tool holder 7 in the housing. The outer part of the anvil protruding from the body (tool holder) is made flat for ease of use in the hand of an engraver (Fig. 3). In the anvil-tool holder 7, an axial central hole 8 is made, as well as a side hole 9 parallel to the central, into which the cutter is inserted and fixed with a bolt. At the other end of the cylindrical body 1, an end cap 10 is installed in the form of a glass inserted into the body. The end cap glass has an end face flange 11, which rests on the end face of the cylindrical body 1. Inside the body 1, between the anvil 7 and the end cap 10, there is a two-stage piston 12 that can move along the body 1. The piston 12 has a through longitudinal and radial channel 13 and separates the cavity housing 1 for three cameras. The first chamber is formed by the end face of the anvil 7 located in the housing, the end and lateral surface of the piston stage 12 of small diameter, one end of the jumper 2 and the inner walls of the cylindrical body 1. This chamber is constantly connected to the atmosphere through a through outlet 4 in the wall of the cylindrical body. The second (central) chamber is formed by the end face of the piston stage 12 of larger diameter, the lateral surface of the piston stage of smaller diameter, the walls of the cylindrical body 1 and the other end of the jumper 2. This chamber is connected to a compressed air source through an inlet 3 in the wall of the cylindrical body. The third chamber is formed by the end face of the piston stage 12 with a larger diameter, the walls of the cylindrical body 1 and the end cap 10. This chamber communicates with the compressed air source through the piston channel 13 and the inlet 3 in the wall of the cylindrical body 1. A handle is installed at the end of the cylindrical body with an end cap 10 14, secured by a threaded connection to the connecting sleeve 15. The connecting sleeve 15 has at the opposite end of the handle an annular groove with a sealing ring 16, which is tightly pressed against the external surface of the housing 1 with the ability to move on a sliding fit on its surface. A longitudinal groove 17 is made on the outer surface of the housing 1 along the connecting sleeve 15 to form a gap between the connecting sleeve 15 and the cylindrical housing 1. Also, an annular ledge 18 is made on the surface of the housing in the form of a flange with an opening for air passage, and a longitudinal groove is made on the connecting sleeve 15 , the end of which rests on a ledge 18 in the housing when moving the connecting sleeve and is a limiter of its movement. The handle 14 may have a mushroom shape for ease of use. Inside the handle 14 has a cavity with a thread 19, which is tightly screwed onto the thread of the connecting sleeve 15 to the ledge 20, made on the outer surface of the connecting sleeve. The step 20 restricts the connection of the handle 14 with the sleeve 15 and due to this between the inner surface of the handle and the end cap 10 there is a gap for the passage of air. In the cavity of the handle 14, a groove is made in the center of the handle in which the needle valve is mounted. The needle valve has a housing 21 with a cavity in which a conical needle 22 with a rod and a spring 23 mounted on the rod is located. The conical needle 22 is located in the seat of the valve body 21, opening or closing the passage of compressed air during the operation of the percussion instrument. The conical needle 22 abuts against the center of the end cap 10 inserted in the cylindrical body 1. The valve body 21 has an annular radial groove 24 in which a through hole for supplying compressed air from the fitting 25 to the cavity of the valve body 21 is made. The fitting 25 is hermetically inserted into the hole, made in the handle 14. To the fitting 25 is connected a silicone hose from a source of compressed air (pressure 0.5-1.5 atm). The valve body 21 is connected to an adjusting screw 26 mounted and fixed in the center of the handle 14. The idle of the impact tool 26 is adjusted with the adjusting screw 26.

The device operates as follows.

The percussion instrument through the fitting 25 is connected to a source of compressed air under a pressure of 0.5-1.5 atm. The engraver operator takes a percussion instrument in his hand and places the blade of a sharpened cutter, for example, on a metal plate (copper, silver, etc.). Applies pressure to the tool so that the cutter cuts slightly into the metal. The cutter is clamped by a screw in the axial central 8 or lateral 9 hole of the anvil 7, which is tightly inserted into the cylindrical body 1 and is fixed with a key 5 from rotation around the axis. The cutter through the anvil 7 exerts pressure on the cylindrical body 1, which begins to move along the connecting sleeve 15, mounted on a sliding fit due to the o-ring 16. In this case, the end cap 10 presses on the needle valve cone 22, compresses the spring 23 and opens the passage for the compressed air. Compressed air from the nozzle 25 through the groove and the hole in the needle valve body 21 passes into its cavity and through the seat open with the tapered needle 22, it enters the gap between the end cap 10 and the inner surface of the handle 14 and the gap between the connecting sleeve 15 and the cylindrical body 1. Then through the inlet opening 3 in the casing fills the central chamber and through the channels in the piston 12 enters the third chamber between the end cap 10 and the end face of the piston 12. The pressure exerted by compressed air on the piston 12 in the central chamber is less than m pressure in the third chamber, as the area of the end surface of the piston is larger than the area of the end surface of the piston stage of a larger diameter. Therefore, compressed air in the third chamber will press on the piston, moving it towards the anvil 7 (Fig. 2). When you hit the anvil 7, a part of the compressed air through the channel in the piston 12 will escape into the first chamber and then into the atmosphere through the outlet 4 with the cylindrical body 1. Having hit the anvil, the piston 12 begins to move up towards the end cap 10 and the compressed chamber will enter air, also moving the piston towards the end cap. When the radial channel of the piston 12 passes through the annular jumper 2 and through the inlet 3 in the housing and the channel in the piston, compressed air begins to flow into the third chamber, exerting pressure on the end face of the piston, the piston will move towards the anvil 7. The cycle will repeat and the piston 12 will oscillate movements in a cylindrical housing 1.

Thus, the proposed percussion instrument is controlled by one operator’s hand with a slight pressure on the cutter mounted on the surface of the processed material. At the same time, the compressed air supply mechanism starts immediately, the piston performs axial vibrations, pushes the cutter forward, performing work with the chip output. In this case, the impact force of the tool will depend on the force of pressure on the cutter. When the pressure on the handle and the cutter ceases, the tool stops and starts working again when the cutter is pressed again. This extends the operational capabilities of the tool, because it is easy to control the process of the work performed by engraving or embossing. The work is more clear with a given depth of cut.

In order to adjust the idle speed of the tool, you need to turn the adjusting screw 26 on the handle 14, which rotates 180 ° C. With a slight rotation, the screw 26 begins to press on the needle valve body 21. This allows you to make a loose fit conical needle 22 in the saddle and create oscillations of the piston 12 at idle. When the adjusting screw 26 is screwed to the end, no-load vibrations will stop. However, the percussion instrument will begin to work when the cutter is pressed on the work surface. The ability to work without idling also expands its operational capabilities.

The second lateral hole 9 in the anvil 7 can be used for calms, and the Central hole 8 for chasing and rootstocks. When using the side opening 9 during operation, the caliper will be closer to the work surface, which will allow the use of shorter caliber. The implementation of the flat tool holder is convenient in operation, because it is easier to hold with your fingers than a round tool holder.

Compared with the prototype, the proposed manual percussion instrument is easy to manufacture, because has a less complex shape of the parts and their simpler processing, for example, the end cap 10 and the connecting sleeve 15 have a simple structure to manufacture. The needle valve, located in the center of the handle, has a simpler design and reliable location, air passes into the device and does not require adapter hoses connecting the holes in the housing. The proposed percussion instrument is made, tested and, when used, shows good results.

The proposed device extends the class of pneumatic hand tools for engraving.

Claims (7)

1. Pneumatic manual percussion instrument for engraving, comprising a cylindrical body with an annular jumper on the inner surface of the body and through holes for air passage before and after the annular jumper, a two-stage piston with a longitudinal and radial channel separating the housing into three chambers is located in the housing an anvil-tool holder with an opening for the cutter is fixed at one end of the cylindrical body, at the other is an end cap in the form of a glass and a handle, while the handle fixed to connect The liner mounted on a sliding fit with the ability to move up to the limiter along the outer surface of the housing has a nozzle for air supply connected to a needle valve in the form of a conical needle blocking the air passage with a stem and a spring and a valve body with a cavity for supplying air from the nozzle, characterized the fact that the needle valve is installed in the groove in the center of the handle, and the conical needle with the rod and spring is abutted in the end cap, which is inserted inside the cylindrical body, while the valve body has an annular radial groove with a through hole for supplying air from the nozzle into its cavity, the coupling sleeve is mounted with a gap between the connection sleeve and the cylindrical body, and between the end plug and the inner surface of the handle is formed by a gap for the passage of air. 2. A pneumatic manual percussion instrument for engraving according to claim 1, characterized in that the end cap in the form of a cup has a flange at the end that is supported by the end face of the cylindrical body. 3. Pneumatic manual percussion instrument for engraving according to claim 1, characterized in that the gap between the end cap and the inner surface of the handle is formed by a threaded connection of the handle to the ledge formed on the surface of the connecting sleeve. 4. A pneumatic manual percussion instrument for engraving according to claim 1, characterized in that the gap between the surface of the cylindrical body and the connecting sleeve is formed by a longitudinal groove on the surface of the cylindrical body. 5. Pneumatic manual percussion instrument for engraving according to claim 1, characterized in that the valve body is connected to an adjusting screw mounted in the center of the handle. 6. Pneumatic manual percussion instrument for engraving according to claim 1, characterized in that a second hole for the cutter is made in the anvil-tool holder, parallel to the central hole. 7. Pneumatic manual percussion instrument for engraving according to claim 1, characterized in that the outer part of the anvil with holes for the cutter has a flat shape.

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